Reverse flow responsive automatic reverse modulation valve system



Jan. 23, 1951 2,539,194

W.. L. KNAUS REVERSE FLOW RESPONSIVE AUTOIATIC REVERSE IODULATION VALVE SVS'I'EI Filed lay 13, 1947 Inventor: William L. Knaus, by (54.94.. 2. 24

His Attorney.

Patented Jan. 23, 1951 REVERSE FLOW RESPONSIVE AUTOMATIC REVERSE MODULATION VALVE SYSTEM William L. Knaus, Upper Montclair, N. .L, assignor to General Electric Company, a corporation of New York Application May 13,1947, Serial No. 747,780

14 Claims.

The invention relates to automatic condition responsive flow modulation valve systems, particularly thermostatically controlled heating and cooling medium flow modulation valve systems of the reversible type such as disclosed and claimed in the Crago Patents 2,121,625 and 2,495,226 and the Levine Patent 2,470,503, all assigned to the present assignee.

The principal object is to provide correlated valve and system improvements for reversing the automatic condition responsive valve flow modulation by reversal of the direction of flow through the system.

The reverse flow responsive reverse modulation valve and system improvements of the present invention, although not limited thereto, are particularly useful in a room heating and cooling medium circulating system, for enabling automatic thermostatic valves to oppositely modulate the flow of heating and cooling medium to the room heat exchange units upon flow thereof in opposite directions through the system so as to increase the flow of heating medium, but decrease the opposite fiow of cooling medium upon a decrease in room temperature and viceversa.

Another object is to provide improved reverse flow responsive valve modulation reversing and interlocking mechanisms that will automatically shift the automatic condition responsive modulation range of the valve upon reversal of the flow modulation. Thus in a thermostatic heating and cooling reverse modulation valve of the character indicated above, the heating modulation range of the valve may be separate from and lower than the reverse cooling modulation range.

Further objects and advantages of the present invention'will appear in the following description of the accompanying drawing in which Fig. 1 is a sectional view of a reverse flow responsive automatic valve modulation reversing mechanism embodying the improvements of the present between the flow passage II formed in one side' of the split valve casing I1 and the communicating flow passage I2 formed in the opposite side of the valve casing I'I dependent upon the direction of flow through the passages as well as upon variations in the condition to which the automatic condition responsive valve actuating bellows I3 is responsive. The flow modulation between the passages I I and I2 is controlled by a pair of alternatively effective spaced apart and reversed valvular members or disks l4 and I5 both carried on the stem I 6 that is movably mounted in the opposite sides of split valve casing I! by means of the sealing bellows l8 and I9 with the upper end of the stem I6 extending into operating relation with the automatic condition responsive valve actuating bellows I3. The biasing spring 2I serves to bias the upper end of the valve stem I6 into operative engagement with the central recess I3a formed in the operating end of the bellows I3.

In order to render the modulation of valve II) automatically reversible in response to the direction of flow therethrough, the complementary interlocking double valve seat member 23 is movably mounted in the valve casing I I in alternative correlation with the opposing valve members I4 and I5 by means of the flexible diaphragm 24 preferably formed of synthetic rubber or the like that is clamped between the opposite sides of the valve casing I! by clamping bolts 22. The double valve seat member 23 moves between the spaced apart alternatively efiective valve members I4 and I5 and is provided with reversed seats on the opposite sides thereof for alternatively cooperating with each of the reversed valve disks I4 and I5 so as to reverse the flow modulation of valve In dependent upon the relative position of the seat member 23. The upward movement of the valve seat member 23 is limited by the stop member 25 and the downward movement of the valve seat member 23 is limited by the stop 28. i i I To provide for flow modulation in difier nt temperature ranges upon reversal in the direction of flow through the valve, the distance A within which the valve seat member 23 is movable between the stops 25 and 26 is substantially greater. than the distance B within which the valve seat member 23 is movable between the opposite faces of the valve disks I 4 and I5. This interlocking range changing relationship is more fully described hereinafter in connection 3|, bellows |3 will contract and spring 2| will move plate 32 that is attached to the stem l6 by means of the sealing nut 33 upwardly. The bellows I3 is removably mounted in the casing 34 by means of the holding-down nut 35 and casing 34 is screw threaded outside to the cylindrical boss 35 on the upper half of the split valve casing H. The sealing bellows I9 is removably clamped to the upper half of the split casing H by means of the annular nut 31 that is threaded inside the boss 36. In a similar way, sealing bellows I8 is removably clamped to the lower half of the split valve casing H by means of the annular clamping nut 38 threaded inside the boss 39. The end of sealing bellows H; is removably clamped to the valve stem l6 by means of the clamping nut 40.

While not necessarily limited thereto, the improved reverse flow responsive automatic valve mechanism of Fig. 1 is particularly adapted for use in an improved reversible heating and cooling medium circulating system such as indicated schematically in Fig. 2. In the system shown each of the valves l0 reversely modulates the flow of heating and cooling medium to one of a plurality of room air conditioning units 43 and 44, with the bulb 3| responsive to the temperature of the room air flowing to the corresponding unit. The room air conditioning units 43 and 44 comprise conduits or tubes which are supplied with heating medium with the flow in one direction from a suitable heating medium supply source 45 and with cooling medium with the flow in the opposite direction from a suitable cooling medium supply source 46. A suitable motor driven circulating pump 41 serves to circulate the heating medium in one direction from the heating medium supply source 45 through supply mains 48 and 49 to the room air conditioning units 43 and 44 in parallel when the heating control valves 59 and 5| are in the open position as shown. Likewise a suitable motor-driven pump 53 serves to circulate the cooling medium in the opposite direction from the cooling medium supply source 49 through the supply mains 48 and 49 to the air conditioning units 43 and 44 in parallel whenever the cooling control valves 54 and 55 are opened. Thus when valves 58 and 5| are closed and valves 54 and 55 are opened by operation of the system changeover valve mechanism 56, the direction of flow-through mains 43 and 44 as well as the automatic reversible flow regulation valves I0 will be reversed.

In order to limit the system pressure differential between the supply mains 48 and 49 provided by the centrifugal circulating pumps 41, a bypass valve 51 of the spring pressed pressure release type is interconnected between the mains 4.8 and 49, as shown in Fig. 2. Thus irrespective of whether the various room unit control valves ID are closed or partially open, a substantially constant pressure differential will be maintained between the mains 48 and 49. As shown, the bypass valve 51 is preferably located near the end oi the mains 48, 49 beyond the point of connectlon of units 43 and 44 with the mains. This insures that a supply of heating medium of proper' temperature is always available to flow through any one of the room heating units whenever the thermostatic control valve |8 thereof operates to start the flow of the heating medium to the corresponding unit.

The reverse acting bypass valve 58 operates in a similar manner to the bypass valve 51 only in the opposite direction when cooling medium is reversely circulated in the mains 48 and 49. The control springs of the bypass valves 51, 58 may be adjusted so as to maintain substantially the same pressure difierential between the mains 48 and 49 during both heating and cooling operation or different pressures as desired.

Where a relatively large number of units are connected with the mains 48, 49 so that there is always likely to be adequate circulation of the heating and cooling medium through the mains, a bypass valve 51' maybe located adjacent the inlet and outlet of the heating medium circulating pump 41 and a reverse bypass valve 58' located adjacent the inlet and outlet of the cooling medium circulating pump 53 as indicated by the dotted lines.

Operation of Figs. 1 and 2 With the improved reverse flow responsive reversible thermostatic flow modulation valve of Fig. 1 connected in the improved reversible heating and cooling medium circulating system such as shown in Fig. 2, the operation is as follows. Since the heating control valves 50 and 5| are open and the cooling control valves 54 and 55 closed, heating medium is circulated by pump 41 to the air conditioning units 43 and 44 with the fiow of the heating medium in a predetermined direction through the valves In as indicated by the solid line arrow in Fig. 1. VThe pressure differential provided by the circulating 'pump 41 is limited by the bypass valve 51. The resulting fluid pressure differential flexes diaphragam 24 ,to the position shown in engagement with the upper motion limit stop 25 and thus carries valve seat 23 into flow regulating relation with the upper valve disk I4. In this way relative movement of the correlated flow regulating elements of the valve is produced in response to flow in a predetermined direction so as properly to position the valve elements for flow regulation of the heating medium in a heating temperature control range.

When the room air temperature to which bulb 3| is responsive decreases into the heating temperature control range, bellows |3 contracts and spring 2| raises the valve stem |8 together with the valve disk |4 so as to provide a variable flow area between the valve seat 23 and the valve disk H as shown in Fig. 1. The resulting flow of heating medium through the corresponding air conditioning unit produces a heat transfer to the room sufficient to balance the heat loss.

I case the heat loss from the room decreases with a resulting increase in the room temperature, then bulb 3| will respond to expand bellows l3 and thereby move valve stem I6 and valve disk |4 downwardly to decrease the flow area between the disk l4 and the valve seat 23. As a result the flow of heating medium to the air conditioning unit will be decreased with a corresponding decrease in the heat transfer to the room so as to again balance the heat loss.

Whenever the ambient temperature conditions require cooling operation of the room air conditioning units, the 'the heating valves 30 and II are closed and the cooling valves ll and II are opened by operation of the system changeover valve operating mechanism 38. This may be accomplished either manually or by a suitable automatic-device responsive to the ambient temperature conditions if desired. Since the flow of the cooling medium through valve III is in the reverse direction as indicated by-the dash line arrow in Fig. l, the fluid pressure dltlerential exerted upon the diaphragm 2l as limited, by valve 58 will be reversed so as to move the valve seat 23 downwardly. However since thedistance B limiting the free travel of the valve seat 23 between the two spaced apart valve disks Il and II is less than the distance A limiting the free movement of the valve seat 23 between the two spaced apart stops 25 and 26, the valve seat 23 will engage with the valve disk IS, in case the valve stem I6 with its valve disks ll and I 5 are in the position shown in Fig. 1. As a result flow oi cooling medium will be stopped since valve disk I5 will then close the port through the valve seat 23 with valve stem I6 in the position shown. Not until bulb 3| responds to an increase in room temperature from the heating control range towards the cooling control range will bellows I3 expand sufilciently to lower valve stem I6 together with valve disk l5. Valve seat 23 will move as a unit along with the valve disk I5, until after the valve seat 23 engages with the lower stop 26 at the lower limit of the cooling control range thereby arresting any further downward movement of the valve seat 23. In this way the improved reverse flow responsive reversible thermostatic valve mechanism oi. the present inventio insures that the cooling control temperature range is separate from and above the heating control temperature range.

Upon further increase in the temperature of the room air in the cooling range, bulb 3I will respond to further expand bellows I3 and thereby continue the downward movement of the valve stem I8 and valve disk I5. Under these conditions valve disk I5 will disengage the valve seat 23 to permit the flow of cooling medium through the corresponding room air conditioning unit so as to provide cooling heat transfer from the room to balance the heat gain. Whenever the heat gain increases, bulb 3| will respond to the increased room temperature and expand bellows I3 to move valve disk I5 farther away from the valve seat 23 and thus increase the cooling heat transfer from the room to balance the heat gain. Likewise, when the heat gain decreases the room temperature willalso decrease and bulb 3| will respond to contract bellows I3 and thereby reposition valve disk I5 so as to again provide the cooling heat transfer from the room required to balance the reduced heat gain.

From the above it will be seen that the improved reverse flow responsive automatic valve mechanism of the present invention effectively reverses the flow modulation characteristic of the valve and also adjusts the operating range of the thermostatic control as required in changing from heating to cooling operation automatically in response to circulation of the heating and cooling medium in opposite directions.

In the modified form of automatic reverse flow responsive valve modulation reversing mechanism embodying the present invention shown in Fig. 3, the valve casing I'Ia is provided with a fixed double valve seat GII having alternative correlations with the two complementary spaced apart valve disks Ila and Ila that are carried by a spool BI formed so as to slide upon the valve stem 62 between the stops 63 and IN with which the stem 62 is provided. The valve disk Ila may be formed integral with the spool GI and the valve disk Ila secured thereto by the anchoring screw 66. The other parts of the valve may be substantially the same as shown in Fig. 1.

In order to insure that the cooling temperature control range is separate from and above the heating temperature control range, the distance 13 representing the free movement of the two spaced apart valve disks Ila and lid between their respective closed positions in engagement with the valve seat is made less than the distance A representing the free sliding movement of the valve spool between the stops 63 and '84.

It should be noted. that the directions of flow for the heating and cooling mediums through the valves as indicated by the solid line and dash line arrows in Fig. 3 are reversed from those shown in Fig. 1. Consequently when the modified form of valve shown in Fig. 3 is used in the heating and cooling medium circulating system such as shown in Fig. 2, the valve casing I'Ia should be connected in the opposite direction to insure proper operation. 7

Operation of Fig. 3

' When cooling medium is supplied to the valve in the direction indicated by the dashed arrow in Fig. 3, then the fluid pressure diii'erential will exert a force upon the sliding spool 6| so as to carry spool 6| into engagement with stop Bl and the lower valve disk I5a into correlated flow modulating relation with the valve seat 6|] as shown. Under these conditions when the temperature of bulb 3I increases, bellows I3 will expand and thereby move valve stem 62 downwardly. Due to the engagement of stop 64 with the upper surfaces of the valve disk Ila, the valve spool BI will be carried along with valve stem 62 so as to move the valve disk I5a away from the.

seat 60. The resulting increased flow of cooling medium will increase the cooling heat transfer from the room so as to balance the increased heat gain. Conversely when thetemperature of bulb 3| decreases, bellows I3 will contrast thereby enabling spring 2| to move valve stem 62 upwardly and thereby carry valve disk I5a, towards the valve seat 60. In this case the resulting decrease in flow of cooling medium will balance the reduced heat gain of the room.

When heating medium is supplied to the valve in the opposite direction as indicated by the full line arrow in Fig. 3, then the fluid pressure differential exerted by the flow upon the sliding spool 6| with its spaced apart disks Ila and I5a will cause the spool BI to slide downwardly towards the stop 63. However, with valve stem 62 and stop 63 in the position shown, valve disk Ila will engage with seat 60, thus stopping the flow as well as arresting the downward movement of spool 6| towards the stop 63. Hence, the valve disk Ila will close the port in the valve seat 63 to stop flow of heating medium until the temperature to which bulb 3| is responsive decreases into the heating modulating range. When the temperature of bulb 3I reaches the heating modulating range, bellows I3 will contract and thereby enable spring 2| to raise valve stem 62 along with stops 63 until the latter engages with the bottom of valve disk I5a. Upon any further decrease in the temperature of bulb 3|, in the heating modulating range, the resulting further contraction of bellows I3 will raise valve stem 62 and stop 63 sumciently to move the double valve spool 8| upwardly as a unit therewith. This separates the valve disk Ila from seat 60 so as to permit the flow of heating medium to the air conditioning unit in a heating temperature modulating range that is below the cooling temperature modulating range. In the heating temperature modulating range, the position of valve disk Me is varied so as to vary the flow or heating medium and thereby vary the heat transfer to the room to balance the heat loss.

In the modification shown in Fig. 4 a single movable valve element I is carried on valve stem Hi and cooperates with the opposing double valve seats I! and 12 in reversely modulating the flow of heating and cooling medium through casing II in opposite directions between the passages II and I2. The valve seat II is formed integral with the annular member I3 having a shoulder I4. The opposing valve seat I2 is similarly formed integral with the annular member I having the shoulder I6. Thus when the two annular members I3 and I5 are screw threaded together as indicated at II the shoulders I4 and I6 tightly clamp the flexible diaphragm 24 therebetween. Also the shoulders 14, I6 engage respectively with the stops 26 and 25 formed in'the valve casing II when diaphragm 24 responds to the reversal of flow. The other parts of the valve may be the same as shown in Fig. 1 and heretofore described so that the valve stem I6 is operated in its downward direction upon heating of the bulb 3| connected to the bellows I3 and in its upward direction when the bellows l3 contracts.

Operation of Fig. 4

With the several parts in their respective position shown in Fig. 4, heating medium is being supplied to the valve casing I! in the direction indicated by the full line arrow. Thus, the pressure differential exerted upon diaphragm 34, due to the circulation of the heating fluid, flexes the diaphragm 24 to carry shoulder I6 into engage ment with stop 25 as shown. As a result, valve seat II is carried into flow modulating relation with the movable valve element I0. Valve element I0 is shown in engagement with the valve seat II, thus indicating that the temperature responsive bulb 3| has responded to the desired temperature in the room to expand bellows l3 suflicient to close the flow control valve and thus stop further supply of heating medium to the room heat exchange unit, assuming the valve of Fig. 4 is used in the system shown in Fig. 2.

As the room temperature decreases, bulb 3| will respond to contract bellows I3 and thereby enable the spring 2| to move the valve stem upwardly and thereby move the movable valve element III away from the valve seat II. As a result, heating medium will fiow through the valve to meet the room heating demand. If the room temperature should increase, bellows I3 will expand and thereby move stem I6 and valve ele ment "I0 towards the seat II so as to reduce the flow of heating medium to balance the heating demand.

. Whenever cooling of the room is required, cooling medium is supplied to the valve with the flow in the reverse direction as indicated by the dash line arrow with a resultant reversal of the pressure differential exerted on the diaphragm 24. Consequently, the diaphragm 24 flexes to carry the shoulder I4 towards the stop 26. However, the distance B representing the amount of free motion of the valve member I0 between the two opposing seats II and I2 is less than the distance A representing the amount or tree motion or the double valve seat members between the stops 25 and 26. Here it the valve member 10 remains in the position shown, valve seat I2 will engage with member ID before shoulder I4 engages with stop 26. Only after bellows I3 has further expanded so as to move valve member III out of the heating temperature control range and into the cooling temperature control range will the valve seat shoulder I4 engage with stop 26.

After the room temperature rises into the cooling temperature control range, the expansion of bellows I3 will then serve to move stem I6 and valve member I0 downwardly so as to disengage the valve member I0 from the valve seat I2 to modulate the flow of cooling medium through the valve to meet the cooling demand.

What I claim as new and desire to secure by Letters Patent of the United States is:

1. An automatic fluid flow regulating valve having in combination, a casing having a passage for alternativeflow of heating and cooling medium in opposite directions therethrough, a. pair of spaced apart jointly movable valve members having a movable double valve seat therebetween for variably restricting said passage, operating mechanism for said valve members including a thermomotive device responsive to varations in a temperature condition controlled by the flow of said medium and provided with connections for moving each of said valve members towards said seat and the other away from said seat upon variation in said condition in a corresponding direction, and a flexible diaphragm responsive to a pressure condition dependent upon the direction of flow of said medium through said passage for moving said seat towards each of said valve members upon flow in the corresponding direction.

2. A heating and cooling medium control valve having in combination a casing having a passage for alternative flow of heating and cooling medium in opposite directions therethrough, a pair of spaced apart jointly movable valve members having a double valve seat movable therebetween into engagement and disengagement with each of said valve members to variably restrict said passage, operating mechanism for jointly 7 moving said valve members in each direction including a thermomotive device responsive to variations in a temperature condition controlled by the flow of said medium, a flexible diaphragm for sealing said seat in said casing and responsive to the reversal of flow of said medium for moving said seat towards each of said valve members upon flow in the corresponding direction, and means including spaced apart stops carried by said casing for limiting movement of said valve seat in each direction after engagement thereof with a corresponding one of said valve members intermediate said stops.

3. An automatic fluid flow regulating valve having in combination, a casing having a passage for alternative flow of heating and cooling medium in opposite directions therethrough, a pair of spaced apart interconnected jointly movable opposing valve seats having a valve member movable therebetween for controlling flow through said passage, 9. thermomotive device responsive to variations in a temperature condition controlled by the flow of said medium for moving said valve member towards each of said valve seats upon variation in said condition in a corresponding direction, and means including a diaphragm movable in response to the reversal of flow of said medium through said passage for moving each of said valve seats towards said movable valve member and the other seat away therefrom upon flow in the corresponding direction.

4. An automatic fluid flow regulating valve having in combination, a casing having a passage for alternative flow of heating and cooling medium in opposite directions therethrough, a pair of spaced apart interconnected jointly movable opposing valve members having a valve seat therebetween for separately controlling flow through said passage, a thermomotive device responsive to variations in a temperature condition controlled by the flow of said mediums and provided with opposed one way lost motion connections for moving either valve member towards said seat when the flow is in a corresponding direction whereby each member is responsive to the reversal of flow through said passage for placing the other of said valve members under control of said device.

5. An automatic fluid flow regulating valve having in combination a casing having a passage for alternative flow of heating and cooling medium in opposite directions therethrough, a pair of spaced apart opposing jointly movable valve seat members having a movable valve member therebetween for variably restricting said passage, operating mechanism for saidr'valve member including a thermomotive device responsive to variations in a temperature condition controlled by the flow of said mediums and provided with connections for moving said valve member towards each of said valve seat members and away from the other valve seat member upon variation in said condition in opposite directions, and a diaphragm responsive to a pressure condition dependent upon the direction of flow of said mediums through said passage and provided with connections for moving each of said valve seat members towards said valve member upon flow in the corresponding direction.

6. An automatic fluid flow regulating valve comprising a casing having a fluid flow path therethrough, fluid flow control mechanism in said casing shiftable into either of two positions to control the flow through said path, automatic means responsive to a predetermined condition for controlling said mechanism to vary the rate of flow of fluid in one direction in one of said positions and in the other direction in the other of said positions, whereby a change of condition in the same sense has opposite effects in said two positions, and means responsive to a change in the direction of flow of the fluid through said path for shifting said mechanism from either of said positions to the other.

'7. An automatic fluid flow regulating valve for eifecting opposite changes in the rate of flow 8. An automatic fluid flow regulating valve for effecting opposite changes in the rate of flow of a fluid under two respective conditions of the fluid, said valve comprising a casing having a fluid flow path therethrough, relatively movable port and port closing members arranged in said path and cooperating to control the flow of fluid through said casing, said members being relatively shiftable into either of two flow regulating positions, automatic means for controlling said members to regulate the flow of fluid in both said positions, and means responsive to the direction of flow of "fluid through said casing for shifting said members from either of said positions to the other, said means including a flexible diaphragm securing one of said members to said casing.

9. An automatic fluid flow regulating valve for effecting opposite changes in the rate of flow of a fluid under two respective conditions of the fluid, said valve comprising a casing having a fluid flow path therethrough, relatively movable port and port closing members arranged in said path and cooperating to control the flow of fluid through said casing, one of said members comprising two spaced elements and being shiftable between two positions to engage corresponding portions of the other of said members, automatic condition responsive means for effecting relative movement of said members to control the rate of flow of fluid in both said positions, and means responsive to the direction of flow of the fluid for shifting said one member from either of said positions to the other.

10. An automatic fluid flow regulating valve for effecting opposite changes in the rate of flow of a fluid under two respective conditions 'of the fluid, said valve comprising a casing having a fluid flow path therethrough, relatively movable port and port closing members arranged in said path and cooperating to' control the flow of fluid through said casing, one of said members comprising two elements having a common axis and spaced apart thereon and the other of said members being coaxial with said one member and lying on said axis intermediate said two elements, said members being shiftable along said axis between two positions for affording cooperation between said other member and respective ones of said two elements, automatic condition responsive means for effecting relative movement between said members in both of said positions whereby opposite of a fluid under two respective conditions of changes in rate of flow are eilected in said two positions upon a like change in the condition, and means responsive to the direction of flow of the fluid for shifting said members from either of said positions to the other.

11. A heating and cooling system comprising a heat exchanger, a source of heating fluid, a source of cooling fluid, means for connecting either of said sources alternatively to said system; said means being arranged to circulate the heating fluid through said heat exchanger in a direction opposite to that of the cooling fluid, an automatic control valve responsive to a condition dependent upon the circulation of said fluid for controlling the rate of flow through said heat exchanger, said control valve having a heating fluid control position and a cooling fluid control position, and means responsive to the direction of flow of fluid through said valve for selectively determining the control position thereof.

12. A heating and a heat exchanger, a source of heating fluid, a source of cooling fluid, means for connecting either of said sources alternatively to said system, means including a changeover mechanism and a pair of pumps for selectively circulating the heating fluid and the cooling fluid through said heat exchanger in opposite directions, an automatic control valve responsive to a condition dependent upon the circulation of said fluid for controlling the rate of flow through said heat exchanger, said control valve having a heating fluid control position and a cooling fluid control position, and means responsive to the direction of flow of fluid through said valve for selectively determining the control position.

thereof.

13. A heating and cooling system comprising a plurality of heat exchangers connected in parallel, a source of heating fluid, a source of cooling fluid, means for connecting either of said sources alternatively to said system, said means being arranged to circulate the heating fluid through said heat exchangers in a direction opposite to that of the cooling fluid, automatic control valves for each heat exchanger responsive to a condition dependent upon the circulation of said fluid through the respective heat exchanger for controlling the rate of flow thereof, each of said control valves having a heating fluid control position and a cooling fluid control position, means responsive to a pressure condition dependent upon the direction of flow of cooling system comprising I i2 fluid through said valves for selectively determining the control positions thereof, and means including a pressure operated valve for bypassing said fluid around said heat exchangers to maintain said pressure condition within predetermined limits.

14. An air conditioning system comprising a heat exchange tube, valve means for controlling the passage or heat exchange fluid through said tube, means for passing a heating fluid in one direction through said tube and valve means, means for passing a cooling fluid in the opposite direction through said tube and valve means, means including a thermostat in the conditioned space for opening and closing said valve means,

and means responsive to the direction of flow of fluid through said valve means and tube for causing said thermostat to adjust said valve REFERENCES orran The following references are of record in the file of this patent:

UNITED STATES PATENTS Number Name Date Re. 22,685 Carrier Oct. 30, 19 .5

2,255,292 Lincoln Sept. 9, 1941 

